DE3008691C2 - Variable nozzle for gas turbine engines - Google Patents

Description

25th

The invention relates to an adjusting nozzle for gas turbine engines according to the preamble of the claim.

An adjusting nozzle of this type, but with four essentially quarter-cylindrical nozzle shells, is off DE-OS 26 18 600 known In this known adjustable nozzle, each nozzle shell is in the central area their upstream edge by means of a hinge joint on the one adjoining the upstream side fixed nozzle. The operating mechanism for swiveling over the nozzle shells known adjusting nozzle has two push rods per nozzle shell, which at the upstream ends hinged to the two longitudinal edges of the nozzle shell and to pivot the nozzle shell essentially in Direction of the nozzle axis are displaceable.

In some gas turbine engines, for example ducted fan engines with variable displacement fans, is it is desirable to move the entire nozzle structure axially away from the jet pipe adjoining upstream to move back to create an additional air inlet between the nozzle structure and the jet pipe to get in reverse thrust operation of the engine.

Such an axial displaceability of the nozzle structure with respect to the jet pipe is flat in FIG discussed known adjustable nozzle because of the fixed! 1 Linkage of the nozzle shells by means of hinge joints not feasible on the nozzle. Another disadvantage of the known adjusting nozzle is the fact that the downstream ends of the nozzle shells are not supported and therefore the entire loads acting on the nozzle shells both by the Gas pressure acting on the inside of the nozzle shells as well as through the external air pressure or air resistance must be absorbed by the hinge joints or the push rods of the operating mechanism.

The invention is based on the object of providing an adjusting nozzle of the type mentioned at the beginning With regard to the possibility of an axial displaceability of the adjusting nozzle with respect to the stationary one To train jet pipe and to better guide the nozzle shells.

This object is achieved according to the invention by the arrangement specified in the characterizing part of the patent claim

An embodiment of the invention will be described in more detail below with reference to the drawings described. It shows

F i g. J a ducted fan gas turbine engine suspended from a pylon of an aircraft with a Verstelldüoe according to the invention,

Fig. 2 the engine with in the star position located adjustment nozzle,

F i g. 3 the engine with in the reverse thrust position located adjusting nozzle, and

F i g. 4 shows the adjusting nozzle with the associated actuation mechanism in an enlarged detail.

1 to 3 show a pylon 10i held ducted fan gas turbine engine 1 with a Baäistriebwerk 2 for driving one of a Blower jacket 4 enclosed, in the drawings not visible blower. The fan jacket 4 is by means of a ring of arranged downstream of the fan stator blades 9 (Fig. 3) rigidly with a not visible central body connected. Because the fan jacket 4 closes downstream as a Adjusting nozzle trained blower jet nozzle 13 through which the blower conveyed by the blower exits

The adjusting nozzle 13 consists of two semi-cylindrical nozzle shells 18 and 19, which are symmetrical are arranged on both sides of the pylon IO carrying the engine and in normal cruise flight condition (Fig. 1) form a continuous downstream extension of the fan jacket 4.

Fig. 4 shows the adjusting nozzle with the associated Actuating mechanism on a larger scale in plan view, with the two nozzle shells 18 and 19 each shown only in the area of their mutually facing longitudinal edges 20 and 21 and otherwise are broken off, and the pylon 10 is only indicated schematically The obce half of the F i g. 4th shows the nozzle shell 18 in the cruising position not swiveled out, while the lower half of FIG. 4th shows the other nozzle shell 19 in the pivoted start position

A flange 22 and 23 is formed on the longitudinal edges 20 and 21 of the two nozzle shells 18 and 19, and these flanges 22 and 23 are each articulated at their upstream end by means of a pivot pin 24 and 25 on a common actuating rod 26/4 , which forms the actuator of the actuating mechanism 26 designed as a hydraulic drive. The actuating rod 26/4 can be moved in the longitudinal direction, ie parallel to the engine axis B, and is guided in a guide 265 formed in the stationary structure a link pin 27 or 28 which engages in a link slot 29 or 30 of a guide plate 31 which is stationary with respect to the actuating mechanism 26 and which is held between the two nozzle shells 18 and 19 on the pylon. The link slots 29 and 30 diverge in the downstream direction so that, when the operating rod 26/4 is in its upstream position det (upper half of FIG. 4), the relevant link pin is located at the upstream end of the relevant link slot. When the actuating rod 26/4 is withdrawn (lower half of FIG. 4), the relevant link pin is located

at the downstream end of the relevant link slot, so that the nozzle shells are swung out. The outlet cross-section is in this operating position the adjusting nozzle is typically around 10% larger than in the case of the nozzle set in the cruise position len, in which their longitudinal edges run parallel to each other.

As a result of the downstream displacement of the pivot pins 24 and 25 when the two pivot Nozzle shells 18 and 19 is a pivoting movement of the nozzle shells without colliding with their apex areas possible with the downstream end of the fixed nozzle ring.

The two diametrically opposite longitudinal edge areas of the two nozzle shells is each assigned an actuating mechanism according to FIG

In addition, a mechanism, not shown, for moving the two nozzle shells 18 and 19 in FIG their swiveled-out position axially away from the stationary nozzle jacket 4 in the downstream direction intended. This allows the Versteli nozzle to be inserted into the in Fig. 3 position shown brought advertise, in which between the downstream end of the nozzle jacket 4 and the upstream ends of the the two nozzle shells 18 and 19, two semicircular openings 32 are formed, which are used as additional Air inlets are used in the thrust reverser of the variable displacement fan of the engine.

This axial displaceability of the two nozzle shells 18 and 19 into a rear operating position can be realized, for example, that the nozzle shells with their longitudinal edges 20 and 21 in on the flanges 22 and 23 formed guides 32 and 33 are guided, with the relative displacement of the Hydraulic drives, not shown, can be provided with respect to the flanges.

Although the two nozzle shells 18 and 19 are not hinged to the fan casing 4 at their upstream edge area, the axial displacement of the pivot pins 24 and 25 in cooperation with the guidance of the link pins 27 and 28 in the link slots 29 and 30 produces a pivoting movement of the nozzle shells, ie the Nozzle shells perform a composite movement when pivoted, which is composed of a straight axial displacement along the engine axis B and a rotary movement around the relevant pivot pin 24 "^ w. 25. The articulation of the Guiding in the downstream area of their long sides results in a stable holding of the nozzle shells despite the lack of articulation of the nozzle sections on the fan jacket.

For this purpose 3 sheets of drawings

Claims (1)

Claim; VerslelldOse for gas turbine engines, consisting of two essentially semi-cylindrical nozzle shells, each of which can be pivoted about an axis running transversely to the nozzle axis and arranged on its upstream edge area, an actuating mechanism with an actuating mechanism that is displaceable in the direction of the nozzle axis and articulated _{to the adjacent long sides of the nozzle shells | 0} Actuator for pivoting the nozzle shells is provided, characterized in that the pivot axis of each nozzle shell (18.19) is formed by swivel joints (24, 25 _{) 5} displaceable in the direction of the nozzle axis and that the pivoting movement is achieved by positive engagement of the actuators via the actuator (26 / 4; axially displaceable nozzle shell (18, 19) with guides (29, 30) which are fixed in relation to the actuating mechanism (26) in the area of the stream-nozzle ends of their long sides